JP5634280B2 - Polarity detection circuit - Google Patents

Description

  The present invention relates to a polarity detection circuit.

  2. Description of the Related Art Today, switching-type power supply devices having excellent characteristics in terms of size reduction, weight reduction, and efficiency are widely used as power supply devices that convert AC voltage into DC voltage. In a switching type power supply device, an AC voltage is first converted into a DC voltage, and then boosting or stepping down is performed so as to obtain a voltage necessary for driving a load.

  With regard to such a switching power supply device, various technologies have been developed to promote stabilization of output voltage, improvement of efficiency, miniaturization, and the like (for example, see Patent Document 1).

Japanese Patent Laid-Open No. 5-64432

  In such a switching type power supply device (hereinafter also referred to as a switching power supply circuit), in order to perform control according to the polarity of the AC voltage, the polarity that detects the polarity of the AC voltage and outputs a signal indicating the detected polarity Detection circuits are widely used.

  An example of such a switching power supply circuit is shown in FIG. A switching power supply circuit 300 illustrated in FIG. 8 includes a rectifier circuit 400, a voltage conversion circuit 500, and a polarity detection circuit 600.

  The rectifier circuit 400 is a circuit that converts an AC voltage between the L terminal and the N terminal of the AC power supply 100 into a DC voltage. The voltage conversion circuit 500 is a circuit that boosts or steps down the DC voltage output from the rectifier circuit 400 to a predetermined voltage determined according to the load 200. The polarity detection circuit 600 is a circuit that detects the polarity of the AC voltage from the AC power supply 100 applied to the switching power supply circuit 300 and outputs various control signals for controlling the rectifier circuit 400 according to the polarity.

  First, a configuration example of the rectifier circuit 400 is shown in FIG. A rectifier circuit 400 shown in FIG. 9 is a synchronous rectifier circuit including four transistors Tr1 to Tr4 (401 to 404) and a capacitor C1 (405).

  The rectifier circuit 400 turns on the transistors Tr1 (401) and Tr4 (404) and turns on the transistors Tr2 (402) and Tr3 (403) when the voltage on the L terminal side of the AC power supply 100 is higher than the voltage on the N terminal side. ) And off. Thereby, the rectifier circuit 400 charges the capacitor C <b> 1 (405) with the current flowing into the rectifier circuit 400 from the L terminal of the AC power supply 100.

On the other hand, when the voltage on the N terminal side of the AC power supply 100 is higher than the voltage on the L terminal side, the rectifier circuit 400 turns off the transistors Tr1 (401) and Tr4 (404) and the transistor Tr2 (402). And Tr3 (403) are turned on. As a result, the rectifier circuit 400 charges the capacitor C1 (405) by the current flowing into the rectifier circuit 400 from the N terminal of the AC power supply 100.
In this way, the rectifier circuit 400 outputs a DC voltage by charging the capacitor C1 (405).

  Next, a configuration example of the voltage conversion circuit 500 is shown in FIG. A voltage conversion circuit 500 shown in FIG. 10 is a chopper type boost converter including a coil L (503), a transistor Tr5 (501), a diode D3 (502), and a capacitor C2 (504). .

  The voltage conversion circuit 500 boosts the voltage applied to the voltage conversion circuit 500 to a predetermined voltage and outputs it by switching the transistor Tr5 (501) with a control signal having a predetermined frequency and a predetermined duty ratio.

  Next, a configuration example of the polarity detection circuit 600 is shown in FIG. A polarity detection circuit 600 shown in FIG. 11 includes diodes D11 and D12 (602, 606), resistors R11 to R14 (603, 604, 607, 608), a constant voltage power supply DC (609), two comparators 601, 602.

  The voltage output from the L terminal of the AC power supply 100 is half-wave rectified by the diode D11 (602) to the non-inverting input terminal of the comparator 601 and then divided by the resistors R11 (603) and R14 (604). A voltage is applied. A voltage from the constant voltage power supply DC (609) is applied to the inverting input terminal of the comparator 601.

  In that case, when the voltage on the L terminal side of the AC power supply 100 rises and the voltage of the non-inverting input terminal of the comparator 601 exceeds the voltage of the constant voltage power supply DC (609), the comparator 601 A control signal (control signal A) having one logic level (for example, Hi) is output (hereinafter also referred to as outputting control signal A).

  On the other hand, when the voltage at the L terminal side of the AC power supply 100 drops and the voltage at the non-inverting input terminal of the comparator 601 falls below the voltage of the constant voltage power supply DC (609), the comparator 601 The logic level is switched to the other logic level (for example, Lo) and output (hereinafter also referred to as stopping the output of the control signal A).

  Similarly to the comparator 601, the comparator 605 outputs a control signal (hereinafter also referred to as a control signal B) from the B terminal or stops output in accordance with the voltage on the N terminal side of the AC power supply 100.

  In the polarity detection circuit 600 shown in FIG. 11, the constant voltage power supply DC (609) is connected to the inverting input terminal of each of the comparators 601 and 605, and the voltage of the non-inverting input terminal is the constant voltage power supply DC (609). The control signals A and B are not output unless the voltage value from is exceeded. This prevents the control signals A and B from being simultaneously output from the two comparators 601 and 605 when the voltage on the L terminal side and the voltage on the N terminal side of the AC power supply 100 are switched. Yes.

  As described above, the polarity detection circuit 600 alternately outputs only one of the control signal A and the control signal B in accordance with the polarity of the AC voltage output from the AC power supply 100. The control signal A is applied to the gate terminals of the transistors Tr1 and Tr4 (401, 404) of the rectifier circuit 400, and the control signal B is applied to the gate terminals of the transistors Tr2 and Tr3 (402, 403). Performs rectification from the AC voltage to the DC voltage described above.

  However, for example, when a lightning strike or a failure of an external power supply facility occurs, the voltage on both the L terminal side and the N terminal side of the AC power supply 100 may increase significantly. In that case, the voltage applied to the non-inverting input terminal of the comparator 601 or the comparator 605, which originally outputs the negative voltage from the AC power supply 100, of the two comparators 601, 605 is the constant voltage power supply DC. There is a possibility that the control signal A or the control signal B that should not be output is output because the voltage from (609) is exceeded.

  Alternatively, as shown in FIG. 11, when charge is accumulated in a noise prevention capacitor 101 called X-cap provided in the AC power supply 100, when the switching power supply circuit 300 is connected to the AC power supply 100. The voltage applied to the non-inverting input terminal of the comparator 601 or the comparator 605 to which the negative voltage is originally output from the AC power source 100 due to the electric charge discharged from the capacitor 101 is the constant voltage power source DC. There is a possibility that the control signal A or the control signal B that should not be output is output because the voltage from (609) is exceeded.

  In these cases, the control signal A and the control signal B are simultaneously output from the two comparators 601 and 605. Then, the internal circuit of the rectifier circuit 400 may be short-circuited, and the rectifier circuit 400 or the switching power supply circuit 300 may be destroyed.

  For this reason, there is a need for a technique that prevents a signal indicating polarity from being erroneously output in a polarity detection circuit that outputs a signal corresponding to the polarity of the AC voltage output from the AC power supply.

  The present invention has been made in view of such a problem, and provides a polarity detection circuit that detects the polarity of an AC voltage and outputs a signal corresponding to the polarity, and does not erroneously output a signal indicating polarity. One purpose.

A polarity detection circuit, which is one means for solving the above problem, is a polarity detection circuit that outputs a signal indicating the polarity of an AC voltage output from an AC power supply, and is a first phase output from the AC power supply. A first diode having an AC voltage applied to the anode, a second diode having a second phase AC voltage that is opposite in phase to the first phase output from the AC power source, and a positive diode A constant voltage power source that outputs a constant voltage, and when the first phase AC voltage is positive, outputs a voltage according to the constant voltage, and when the first phase AC voltage is negative, the second phase A first reference voltage output circuit that outputs a voltage corresponding to the voltage of the cathode of the diode; a first voltage that corresponds to the voltage of the cathode of the first diode; and a voltage output from the first reference voltage output circuit; Compare the results of the comparison Flip and, and a first signal output circuit for outputting a signal indicating the polarity of the AC voltage of the first phase.
In addition, the problems disclosed by the present application and the solutions thereof will be clarified by the description in the column of the embodiment for carrying out the invention and the description of the drawings.

  According to the present invention, it is possible to prevent a signal indicating polarity from being erroneously output in a polarity detection circuit that detects the polarity of an AC voltage and outputs a signal corresponding to the polarity.

It is a figure which shows the structural example of the switching power supply circuit which concerns on this embodiment. It is a figure which shows the structural example of the polarity detection circuit which concerns on this embodiment. It is a figure for demonstrating operation | movement of the polarity detection circuit which concerns on this embodiment. It is a figure for demonstrating operation | movement of the polarity detection circuit which concerns on this embodiment. It is a figure which shows the structural example of the switching power supply circuit which concerns on this embodiment. It is a figure which shows the structural example of the synchronous rectification circuit which concerns on this embodiment. It is a figure which shows the structural example of the bridgeless boost circuit which concerns on this embodiment. It is a figure which shows the structural example of the switching power supply circuit which concerns on this embodiment. It is a figure which shows the structural example of the rectifier circuit which concerns on this embodiment. It is a figure which shows the structural example of the voltage converter circuit which concerns on this embodiment. It is a figure which shows the structural example of the polarity detection circuit for demonstrating this embodiment.

  FIG. 1 shows a configuration diagram of a switching power supply circuit 1200 including the polarity detection circuit 700 according to the present embodiment as a component.

  The switching power supply circuit 1200 is a circuit that converts an AC voltage output from the AC power supply 100 into a predetermined DC voltage corresponding to the load 200 and outputs the DC voltage to the load 200.

  The AC power supply 100 can be a commercial three-wire single-phase AC power supply 100, for example. The AC power supply 100 shown in FIG. 1 outputs, for example, a first-phase AC voltage from an L (live) terminal and a second-phase AC voltage whose phase is opposite to that of the first phase from an N (neutral) terminal. Is output. Since the AC voltages of the first phase and the second phase are opposite in phase, when one is at the positive electrode and the other is at the negative electrode, the other is at the positive electrode with respect to the neutral phase voltage of the AC power supply 100 One is in the negative electrode.

  Of course, the AC power supply 100 may output a single-phase AC voltage generated by combining the AC voltages of the respective phases output from the multiphase (for example, three-phase) AC power supply 100.

The load 200 is an electronic device that operates with a DC voltage. The load 200 can be various electronic devices such as a computer, a digital camera, a mobile phone, a music player, and a game machine.
The switching power supply circuit 1200 includes a rectifier circuit 400, a voltage conversion circuit 500, and a polarity detection circuit 700.

  The rectifier circuit 400 converts an AC voltage between the L terminal and the N terminal of the AC power supply 100 into a DC voltage. The rectifier circuit 400 may be, for example, a bridge rectifier circuit using a diode or a synchronous rectifier circuit using a switching element such as a transistor.

  A configuration example of the rectifier circuit 400 according to the present embodiment is shown in FIG. A rectifier circuit 400 shown in FIG. 9 is a synchronous rectifier circuit including four transistors Tr1 to Tr4 (401 to 404) and a capacitor C1 (405).

  The rectifier circuit 400 turns on the transistors Tr1 (401) and Tr4 (404) and turns on the transistors Tr2 (402) and Tr3 (403) when the voltage on the L terminal side of the AC power supply 100 is higher than the voltage on the N terminal side. ) And off. Thereby, the rectifier circuit 400 charges the capacitor C <b> 1 (405) with the current flowing into the rectifier circuit 400 from the L terminal of the AC power supply 100.

On the other hand, when the voltage on the N terminal side of the AC power supply 100 is higher than the voltage on the L terminal side, the rectifier circuit 400 turns off the transistors Tr1 (401) and Tr4 (404) and the transistor Tr2 (402). And Tr3 (403) are turned on. As a result, the rectifier circuit 400 charges the capacitor C1 (405) by the current flowing into the rectifier circuit 400 from the N terminal of the AC power supply 100.
In this way, the capacitor C1 (405) is charged, whereby a DC voltage is output from the rectifier circuit 400.

  In order to effectively function the conversion function from the AC voltage to the DC voltage by the rectifier circuit 400, the polarity of the AC voltage output from the AC power supply 100 is detected correctly, and the transistors Tr1 to Tr4 (401 are detected according to the polarity. -404) must be switched correctly.

  As will be described in detail later, the polarity detection circuit 700 according to the present embodiment controls the voltage when the voltage on the L terminal side is higher than the voltage on the N terminal side according to the polarity of the AC voltage output from the AC power supply 100. When the signal A is output and the voltage on the N terminal side is higher than the voltage on the L terminal side, the control signal B is output. The control signal A is input to the transistors Tr1 (401) and Tr4 (404), and the control signal B is input to the transistors Tr2 (402) and Tr3 (403).

  In this way, the rectifier circuit 400 converts the AC voltage to the DC voltage by correctly switching the transistors Tr1 to Tr4 (401 to 404) in the rectifier circuit 400 according to the polarity of the AC voltage. .

The voltage conversion circuit 500 boosts or lowers the DC voltage output from the rectifier circuit 400 to a predetermined voltage determined according to the load 200.
A configuration example of the voltage conversion circuit 500 is shown in FIG. A voltage conversion circuit 500 shown in FIG. 10 is a chopper type boost converter including a coil L (503), a transistor Tr5 (501), a diode D3 (502), and a capacitor C2 (504). .

  The voltage conversion circuit 500 boosts the voltage applied to the voltage conversion circuit 500 to a predetermined voltage and outputs it by switching the transistor Tr5 (501) with a control signal having a predetermined frequency and a predetermined duty ratio.

The polarity detection circuit 700 detects the polarity of the AC voltage from the AC power supply 100 applied to the switching power supply circuit 1200 and outputs a signal indicating the polarity.
A configuration example of the polarity detection circuit 700 according to this embodiment is shown in FIG. The polarity detection circuit 700 shown in FIG. 2 includes a diode D1 (first diode) 703, a diode D2 (second diode) 709, resistors R1 to R10 (703 to 707, 710 to 714), and a constant voltage power source DC (715). ) And two comparators (first signal output circuit, second signal output circuit) 701 and 708.

  The polarity detection circuit 700 outputs a control signal A from the comparator 701 when the voltage on the L terminal side of the AC power supply 100 is higher than the voltage on the N terminal side, and the voltage on the N terminal side is higher than the voltage on the L terminal side. If it is higher, the control signal B is output from the comparator 708.

  Next, the operation of the polarity detection circuit 700 according to this embodiment will be described with reference to FIGS. 3 and 4. FIG. 3 illustrates the operation when the control signal A is output from the comparator 701 in accordance with the polarity of the AC voltage output from the AC power supply 100. The same applies to the operation when the control signal B is output from the comparator 708.

  FIG. 4 is a diagram showing voltage waveforms at various parts in the polarity detection circuit 700. In FIG. 4, ACIN indicates the potential on the L terminal side with respect to the neutral phase potential of the AC power supply 100. Further, a + represents a non-inverting input terminal of the comparator 701, a− represents an inverting input terminal of the comparator 701, and A represents an output terminal of the comparator 701. Further, b + represents a non-inverting input terminal of the comparator 708, b− represents an inverting input terminal of the comparator 708, and B represents an output terminal of the comparator 708.

  As shown in FIG. 3, the L terminal of the polarity detection circuit 700 according to this embodiment is connected to the L terminal of the AC power supply 100, and the N terminal of the polarity detection circuit 700 is connected to the N terminal of the AC power supply 100.

  First, when the voltage applied to the L terminal of the polarity detection circuit 700 is positive, a positive voltage is applied to the anode of the diode D1 (702), so the AC power supply 100 is applied to the cathode of the diode D1 (702). A voltage substantially equal to the voltage output from the L terminal is output. Therefore, a voltage (first voltage) corresponding to the cathode voltage of the diode D1 (702) is applied to the non-inverting input terminal (a +) of the comparator 701.

  Specifically, the voltage of the cathode of the diode D1 (702) is the resistance R1 (703), the resistance R3 (704), the resistance R5 (705), the resistance R8 (713), the resistance R10 (714), the constant voltage power supply DC. The first voltage is output by being divided by the circuit configured by (715), and is applied to the non-inverting input terminal (a +) of the comparator 701.

  At this time, since the voltage applied to the N terminal of the polarity detection circuit 700 is negative, a negative voltage is applied to the anode of the diode D2 (709). Therefore, a voltage (first reference voltage) corresponding to the constant voltage output from the constant voltage power supply DC (715) is applied to the inverting input terminal (a−) of the comparator 701. Specifically, the constant voltage output from the constant voltage power supply DC (715) is applied to the inverting input terminal (a−) of the comparator 701 as a resistor R9 (707), a resistor R7 (706), and a resistor R6 (712). ) Is applied (the first reference voltage).

  When the voltage (first voltage) applied to the non-inverting input terminal of the comparator 701 is higher than the voltage (first reference voltage) applied to the inverting input terminal, the comparator 701 A signal indicating that the AC voltage output from the L terminal is positive is output. Specifically, the comparator 701 sets the level of the signal output from the A terminal to one logical level (for example, Hi) and outputs it. This is shown in the waveforms indicated by A in Phases I and III in FIG.

  On the other hand, when the voltage applied to the L terminal of the polarity detection circuit 700 is negative, a negative voltage is applied to the anode of the diode D1 (702), and thus the voltage at the non-inverting input terminal (a +) of the comparator 701. Is almost zero volts.

  At this time, since the voltage applied to the N terminal of the polarity detection circuit 700 is positive, a positive voltage is applied to the anode of the diode D2 (709). Therefore, a voltage substantially equal to the voltage output from the N terminal of the AC power supply 100 is output to the cathode of the diode D2 (709).

  Therefore, a voltage (first reference voltage) corresponding to the cathode voltage of the diode D2 (709) is applied to the inverting input terminal (a−) of the comparator 701. Specifically, the voltage of the cathode of the diode D2 (709) is the resistance R2 (710), the resistance R4 (711), the resistance R6 (712), the resistance R7 (706), the resistance R9 (707), the constant voltage power supply DC. The first reference voltage is output by being divided by the circuit configured by (715), and is applied to the inverting input terminal (a−) of the comparator 701.

  When the voltage applied to the inverting input terminal (first reference voltage) is higher than the voltage applied to the non-inverting input terminal of the comparator 701 (first voltage), the comparator 701 uses the AC power supply. The signal which shows that the alternating voltage output from L terminal of 100 is a negative electrode is output. Specifically, the comparator 701 outputs the signal output from the A terminal with the other logical level (for example, Lo). This is shown in the waveforms indicated by A in Phases II and IV of FIG.

The operation when the control signal A is output from the comparator 701 has been described above, but the same applies to the operation when the control signal B is output from the comparator 708.
By configuring the polarity detection circuit 1200 according to the present embodiment as described above, it is possible to prevent a signal indicating polarity from being erroneously output.

  For example, when the AC voltage output from the L terminal of the AC power supply 100 is at the negative electrode, when a lightning strike or a failure of an external power supply facility occurs, or when the charge remains in the X-cap (101) A case where the power is turned on and the voltages on both the L terminal side and the N terminal side of the AC power supply 100 are greatly increased will be described.

  In this case, since the voltage applied to the L terminal of the polarity detection circuit 700 is positive, a voltage corresponding to the cathode voltage of the diode D1 (702) is applied to the non-inverting input terminal of the comparator 701. Become.

  However, at this time, since the voltage applied to the N terminal of the polarity detection circuit 700 is also positive, a voltage corresponding to the cathode voltage of the diode D2 (709) is applied to the inverting input terminal of the comparator 701. Yes.

  That is, even if the first voltage applied to the non-inverting input terminal of the comparator 701 rises when the AC voltage output from the L terminal of the AC power supply 100 is originally in the negative polarity, it is applied to the inverting input terminal of the comparator 701. Since the first reference voltage also rises, the comparator 701 correctly detects that the AC voltage output from the L terminal of the AC power supply 100 is a negative electrode, and does not erroneously output a signal indicating the polarity of the AC voltage.

  The polarity detection circuit 700 according to the present embodiment uses an AC voltage as an input, and converts the input voltage to a half wave by diodes D1 (702) and D2 (709) connected to the live (L) side and the neutral (N) side, respectively. It is a circuit that is input to the + terminal and the − terminal of the comparator (comparator) after rectification. The comparator has two of A (701) and B (708). The + terminal of the comparator A (701) is R1 (703) connected to the L side, and the-terminal is resistors R7 (706) and R4 ( 711) is connected to R2 (710) connected to the N side via the other terminal, and the + terminal of the other comparator B (708) is connected to R2 (710) connected to the N side, and the-terminal is a resistor R8 (713). ), And R1 (703) connected to the L side via R3 (704). Further, the negative terminals of the two comparators have a circuit configuration in which the voltage is raised by a DC bias.

  Thus, the polarity detection circuit 700 detects the polarity of the AC by outputting a signal corresponding to the polarity of the input from the comparator to determine whether the AC input voltage is positive or negative. In the polarity detection circuit 700, a voltage having a phase opposite to that of the + terminal is input to the reference voltage input to the − terminal of the comparator with a voltage level lowered by a resistor.

  For example, a voltage obtained by rectifying an input voltage that is a sine wave with diodes D1 (702) and D2 (709) is input to the + terminal of the comparator. Further, after the voltage of the opposite phase passes through the resistor, the voltage is raised by the DC bias and used as the input of the negative terminal of the comparator. The comparator determines the output timing based on the two signals of the positive terminal and the negative terminal.

  At this time, in an actual electric circuit, there is a noise prevention circuit in which a capacitor (C) called X-cap (101) is combined in the input section, so that charge remains in C depending on the timing of cutting off the input voltage. In some cases, it may be thrown in.

  If the polarity is not correctly distributed, the cathode voltage of D1 (702) and D2 (709) may be generated at the same time depending on the timing of the phase of the input voltage when the charge is left in C. Two comparators may output signals simultaneously.

  However, in the polarity detection circuit 700 according to the present embodiment, since a negative-phase (counterpart) voltage is input to the detection terminal of the comparator, for example, the N side is positive with the positive charge remaining on the L side. Even when the signal is input at the same time, the phase is detected and output by the difference between the voltages of D1 (702) and D2 (709), so that simultaneous output of the comparators (701, 708) can be avoided.

  In addition, in order to prevent signals from being simultaneously output from the comparators A (701) and B (709), a non-reaction time called a dead time is provided at the moment when the outputs of the comparators A (701) and B (709) are switched. In the polarity detection circuit 700, the dead time adjustment range can be expanded by applying a DC bias to moderate the voltage change of the pulsating current obtained by rectifying the AC and injecting it into the negative terminal.

  As described above, in an electric circuit having an AC voltage as an input, it is effective in improving efficiency and adding functional value to detect the polarity of the AC voltage and cause the circuit to perform an operation corresponding to each polarity. For example, even when rectification is performed, it is possible to suppress loss by controlling the phase switching element according to the polarity of the AC voltage. This can be dealt with by detecting the voltage polarity.

Examples in which the polarity detection circuit 700 according to this embodiment is used in such various circuits are shown in FIGS.
The circuit shown in FIG. 5 is a circuit in which the AC / DC converter 800 converts the AC voltage output from the AC power supply 100 into a direct current and supplies it to the load 200. The polarity detection circuit 700 detects the polarity of the AC voltage, This is an example in which the control circuit 900 controls the AC / DC converter 800 in accordance with the polarity of the AC voltage by inputting signals A and B indicating the polarity of the voltage to the control circuit 900.

  The circuit shown in FIG. 6 is a circuit in which an AC voltage output from the AC power supply 100 is rectified to a direct current by a synchronous rectifier circuit 400 and supplied to a load 200. A polarity detection circuit 700 detects the polarity of the AC voltage, In this example, signals A and B indicating the polarities of the signals are input to switching elements in the synchronous rectifier circuit 400.

  The circuit shown in FIG. 7 converts the AC voltage output from the AC power supply 100 into a DC voltage without using a bridge circuit, and detects the polarity in the bridgeless boost circuit 1000 that boosts the voltage to a predetermined voltage according to the load 200. In this example, the circuit 700 is applied.

  As described above, according to the polarity detection circuit 700 according to this embodiment, the polarity detection circuit that detects the polarity of the AC voltage and outputs a signal corresponding to the polarity does not erroneously output a signal indicating the polarity. It becomes possible to

  Also, according to the polarity detection circuit 700 according to the present embodiment, a low-loss rectifier circuit can be used, and the power consumption of the circuit can be suppressed. Further, since not only the input but also the AC output can be detected, the output of the inverter such as a motor drive can also be detected.

  The preferred embodiments of the present invention have been described above, but these are merely examples for explaining the present invention, and the scope of the present invention is not limited to the present embodiments. The present invention can be implemented in various other forms.

100 AC Power Supply 700 Polarity Detection Circuit 701 Comparator 702 Diode 708 Comparator 709 Diode 715 Constant Voltage Power Supply 1200 Switching Power Supply Circuit

Claims (4)

A polarity detection circuit that outputs a signal indicating the polarity of an AC voltage output from an AC power source,
A first diode to which a first-phase AC voltage output from the AC power source is applied to an anode;
A second diode in which an AC voltage of a second phase opposite in phase to the first phase output from the AC power source is applied to the anode;
A constant voltage power source that outputs a positive constant voltage;
When the AC voltage of the first phase is a positive electrode, a voltage corresponding to the constant voltage is output. When the AC voltage of the first phase is a negative electrode, a voltage corresponding to the voltage of the cathode of the second diode is output. A first reference voltage output circuit for outputting;
The first voltage corresponding to the voltage of the cathode of the first diode is compared with the voltage output from the first reference voltage output circuit, and the polarity of the AC voltage of the first phase is determined according to the comparison result. A first signal output circuit that outputs a signal indicating
A polarity detection circuit comprising: The polarity detection circuit according to claim 1,
The first signal output circuit outputs a signal indicating that the first-phase AC voltage is positive when the first voltage is higher than the voltage output from the first reference voltage output circuit. A polarity detection circuit. The polarity detection circuit according to claim 1,
When the second-phase AC voltage is positive, a voltage corresponding to the constant voltage is output. When the second-phase AC voltage is negative, the second-phase AC voltage corresponds to the cathode voltage of the first diode. A second reference voltage output circuit for outputting a voltage;
The second voltage according to the voltage of the cathode of the second diode is compared with the voltage output from the second reference voltage output circuit, and the polarity of the AC voltage of the second phase according to the comparison result A second signal output circuit for outputting a signal indicating
A polarity detection circuit comprising: The polarity detection circuit according to claim 3,
The first signal output circuit outputs a signal indicating that the first-phase AC voltage is positive when the first voltage is higher than the voltage output from the first reference voltage output circuit. And
The second signal output circuit outputs a signal indicating that the second-phase AC voltage is positive when the second voltage is higher than the voltage output from the second reference voltage output circuit. A polarity detection circuit.

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